DE1186542B - DC voltage monitoring circuit - Google Patents

Description

DC voltage monitoring circuit For good effect of individual commercial Telecommunication devices and many measuring devices are required to that one or more supply voltages for the receiving or transmitting apparatus or remain within certain limits for the measuring device. This requirement will generally by means of one or more dc voltage stabilizers Fulfills. But these do not always work flawlessly, and they are also capable they only keep the supply voltage between certain narrow limits if the applied voltage to be stabilized does not change too much. Unusual Strong changes can occur, especially when fed via a transmission line Telecommunication devices occur as a result of a sharp change in the line attenuation. Such changes can be a practical disconnection or a result in impermissible distortion or crosstalk. Put in measuring devices such unnoticed changes lead to unnoticed, often serious measurement errors Reason.

About the very detrimental consequences of exceeding it under certain circumstances to restrict the permissible limits by a supply voltage to a minimum and also to display the impermissible changes in this voltage, it is known to use a monitoring circuit which works as a bistable trigger contains a feedback amplifier and a reference voltage source which has a control electrode an amplifier element of the amplifier polarized in such a way that at input DC voltages with a value that is on a certain side of a threshold value, the main circuit this element is practically blocked. To obtain a DC voltage in terms of the You could naturally monitor exceeding a maximum and minimum value a combination of two such circuits, e.g. B. to control the excitation of a Relay, apply. The monitoring circuit constructed in this way would be in relation to the intended goal, relatively extensive, expensive and The present invention provides a very simple DC voltage monitor circuit of the type described, through which a DC voltage both in terms of exceeding a minimum value as well as a maximum value can be monitored. This circuit is characterized by the gain and the feedback factor of the amplifier are chosen such that, if the input DC voltage exceeds the threshold value exceeds, this amplifier oscillates and that the main circuit of an amplifier element contains such a high load resistance that when the input DC voltage exceeds a second threshold value, this amplifier element is saturated, so that the gain of the amplifier, including its feedback, is smaller becomes one and the amplifier no longer oscillates. A relay can do so be coupled to the amplifier that it will oscillate depending on or Not oscillating the amplifier is excited.

The invention is explained in more detail with reference to the drawing, in which two figures show the circuit diagrams of two exemplary embodiments of the DC voltage monitoring circuit are shown according to the invention.

The in F i g. 1 shown DC voltage monitoring circuit contains a feedback amplifier with transistors 1 and 2, in this case the pnp kind. The two transistors are connected to the negative terminal Vv of a voltage source fed, at the same time a reference voltage by means of a resistor 3 and a Zener diode 4 working as a stabilizer is taken. The emitter electrodes of the two transistors are connected to earth and to the positive terminal of the supply source bridged by capacitors 6 and 8 respectively Resistors 5 and 7. The collector electrode of transistor 1 is connected to the common terminal of the resistor 3 and the diode 4 and thus at the stabilized voltage across the primary winding 9 of a coupling transformer 10 and a resistor 12 of such a value that this Transistor can be saturated relatively easily. The base electrode of the Transistor 1 is connected to the input terminal via a series resistor 13. A resistor 14 together with the emitter resistor 5 forms a voltage divider, so that when the Transistor 1 kept its emitter electrode at a stabilized reference potential will.

The transformer 10 has a secondary winding 11 in the base circuit of transistor 2 is in series with one bridged by a capacitor 16 Base resistor 15. The collector circuit of transistor 2 contains the excitation winding 17 of a relay that is directly connected to the Vv terminal. The circuit includes furthermore a detector with a diode 18 and a resistor 19 through which the Diode is polarized in the reverse direction. The common point of resistance 19 and the diode 18 is connected to the collector electrode of the by means of a capacitor 20 Transistor 2 coupled.

The resistor 19 is on the one hand due to the stabilized supply voltage, and the cathode of the diode 18 is connected to the emitter electrode of the transistor 2. With the common point of this diode and this resistor is another one Diode 21 connected in the forward direction. The anode of this diode is again with the common point of the secondary winding 11 and the base resistor 15 a resistor 22 and to the base electrode of the transistor 1 via a capacitor 23 coupled.

When an input voltage V1 is present, transistor 1 is blocked, since its emitter electrode has a negative reference potential, while its Base electrode is connected to earth. The transistor 2 is but weakly energized, as its base electrode via resistor 19, diode 21, resistor 22 and the winding 11 is supplied with a small forward voltage. Its quiescent current is about 0.5 mA.

If one is connected to the upper input terminal and via the resistor 13 to the base electrode of the transistor 1 applied negative voltage Vi a first When the threshold value is reached, this transistor becomes live. This threshold is slightly larger than the stabilized reference voltage of its emitter electrode.

As soon as the transistor is energized, the amplifier begins as Relaxation oscillator to work, since the gain on the transistor 1, the Transformer 10, the transistor 2, the capacitor 20, the diode 21 and the capacitor 23 existing closed loop is greater than one.

The frequency of the vibrations generated by the transformer 10 and due to the coupling network with the capacitors 20 and 23, which Network also has certain phase-shifting properties. The transistor 1 is alternately saturated and blocked, and those generated on winding 17 and over The vibrations transmitted to the capacitor 20 are rectified by the diodes 18 and 21, which together with the capacitors 20, 16 and 8 have a voltage doubling rectifier form. The common Point of resistor 19 and diode 18 initially a negative threshold potential, both by the voltage on the zener diode 4 and the value of the resistors 19, 22 and 15 as well as the base current of the transistor 2 in the idle state and due to the initial forward resistance of the diode 21 is. By rectifying the generated vibrations, this common point becomes more negative, so that the base electrode of the transistor 2 via the diode 21 and the resistor 22 applied negative bias voltage also increases.

The transistor 2 is heavily energized, and the relay with the excitation winding 17 is excited.

This effect is further enhanced by the fact that the resistance of the Diode 21 decreases with increasing current through this diode.

If the negative potential at the upper input terminal continues to increase, the amplifier continues to oscillate and the relay with the excitation winding 17 remains excited until the value of this potential exceeds a second threshold value. When the negative input potential increases, the mean base current actually increases of the oscillating transistor 1 and therefore also its collector current until this Transistor due to the presence of resistor 12 is saturated, being mean collector potential only a little of its stabilized emitter potential deviates. If this is the case, the gain via the amplifier and increases its feedback loop decreases considerably, since transistor 1 is practically nonexistent more amplified, and the circuit will stop oscillating.

When the value of the negative input potential decreases again, begins the amplifier will oscillate again as soon as this value reaches the second threshold falls below and the transistor 1 comes out of its saturation state. Of the The amplifier then continues to oscillate until the negative input potential is below dropped the first threshold value and the transistor 1 is blocked again.

As a result of the DC feedback through the diode 21 and the resistor 22 the relay is always energized when the amplifier is oscillating, during the quiescent current of transistor 2 to excite this relay is not sufficient.

The diode 21 can of course be characterized by another variable impedance are replaced, the value of which depends on the rectified amplifier oscillations changes in such a way that the feedback factor in the presence of amplifier oscillations increases. In this case, however, the effect of the rectifier would be less good. The presence the diode 21 or some other such variable impedance is for the reason important to thereby cause a sudden energization or tripping of the relay in dependence from the DC input voltage.

Instead of the transformer 10, as in FIG. 2 shown, the collector electrode of the first transistor 1 by means of an RC network 12, 25 are coupled to the base electrode of the second transistor 2. This changes not much in the way the amplifier works, because this amplifier works as a relaxation oscillator as soon as the negative potential at the upper input terminal den exceeds the aforementioned first threshold. Using a transformer however, the circuit becomes more sensitive and / or transistors can be used with use a smaller current gain.

In the embodiment according to FIG. 2 becomes the excitation current for the relay 17 is supplied by a third transistor 24. This transistor is with the relaxation oscillator coupled to transistors 1 and 2 by means of transformer 10, whose primary winding 9 is in the collector circuit of transistor 2 and its secondary winding 11 forms the base-emitter circuit of the transistor 24, such that a current pulse through the collector circuit of transistor 2 a forward current pulse in the base-emitter circuit of transistor 24 is generated. The transistor's low forward input resistance 24, by means of the transformer 10, the output impedance of the transistor 2 is strong adapted current-conducting state, so that the transistor 24 with each current pulse is saturated by the collector circuit of transistor 2. With the transistor blocked 2, the transistor 24 is also blocked.

There is a small parallel to the primary winding 9 of the transformer 10 Capacitor 26 to round off the waveform of the collector current pulses somewhat and thus suppressing high superharmonics.

In parallel with the secondary winding 11 is a rectifier 18, the large counter-voltage peaks generated when the transistor 2 is blocked is suppressed. This rectifier could also be replaced by a damping resistor.

In the emitter circuit of the transistor 24 there is a load resistor 27, to which an alarm voltage is generated via a smoothing network in the event of an oscillating trigger 28.29 can be taken.

The excitation winding of the is located in the collector circuit of the transistor 24 Relay 17 in parallel with a diode 30 to suppress the when suppressing the Excitation current through this winding occurring voltage peaks. In the end there is a larger capacitor 31 between the emitter and collector electrodes of transistor 24. When the trigger oscillates with transistors 1 and 2, this capacitor via the emitter-collector path of the transistor 24 periodically discharged and periodically charged through the winding of the relay 17 and the resistor 27, so that the relay 17 is continuously energized by a direct current.

In the two exemplary embodiments described, the course the base current-base voltage curve of the input transistor 1 with temperature easily by means of a resistor in parallel or in series with resistor 14 be compensated with a negative temperature coefficient. Could for the same purpose one also has a resistor with a positive temperature coefficient in parallel or in Use series with resistor 5. That way, however, you'd get the two of them Threshold values of the monitoring circuit influence what is not desired, because the second threshold value is almost within the permissible temperature range is independent of the temperature.

The DC voltage monitoring circuit described can be used in all such cases apply where a DC voltage or one of any Size derived DC voltage can be kept between two specific limits must, e.g. B. to monitor and / or control any chemical or physical Operation. It is particularly suitable as an alarm circuit for an alarming Pilot receiver of a telecommunications system.

Claims (11)

Claims: 1. DC voltage monitoring circuit with a feedback amplifier and a reference voltage source, which has a control electrode an amplifier element of the amplifier polarized in such a way that at input DC voltages with a value that is on a certain side of a threshold value, the main circuit this element is practically blocked, d a -characterized by the fact that the gain and the feedback factor of the amplifier are chosen such that when the inputs are equal to voltage (Vi) exceeds the threshold mentioned, this amplifier oscillates and that the main circuit of an amplifier element has such a high load resistance contains that when the DC input voltage exceeds a second threshold value, this amplifier element is saturated, so that the gain of the amplifier, including its feedback, becomes less than one and so does the amplifier no longer oscillates. 2. Circuit according to claim 1, characterized in that a relay (17) is coupled to the amplifier in such a way that it is a function of oscillating or not to excite the amplifier. 3. Circuit according to claim 1 or 2, characterized in that the difference between the DC input voltage to be monitored (Vi) and the Reference voltage to the input electrodes of a first amplifier element (1) of the amplifier is supplied, the main circuit of which has the aforementioned high load resistance contains. 4. A circuit according to claim 1, 2 or 3, characterized in that a rectifier (21) is coupled to the amplifier, which by rectification of the amplifier oscillations a polarization voltage for a control electrode Amplifier element (2) generated (F i g. 1). 5. Circuit according to claims 2 and 4, characterized in that that the excitation current of the relay of the mentioned, polarized by means of the rectifier Amplifier element is controlled. 6. Circuit according to claim 4 or 5, characterized in that the amplifier element controlled with the aid of the rectifier part of the feedback Amplifier forms so that with the help of the rectifier a positive direct current feedback is brought about. 7. Circuit according to claims 5 and 6, characterized in that that an excitation winding of the relay as the load impedance of the means of the rectifier controlled amplifier element is used and that the voltage generated at this winding is fed to the rectifier. 8. Circuit according to claim 4 or 5, characterized in that the amplifier's feedback circuit contains a variable impedance element, whose value is regulated as a function of the rectified amplifier oscillations becomes, such that the feedback factor in the presence of Amplifier vibration increases. 9. A circuit according to claim 8, characterized in that the relevant The element with variable impedance is a rectifier element (21) (Fig. 1). 10. Circuit according to claims 6 and 9, characterized in that that the rectifier element in question in series with a resistor (22) in the positive DC feedback circuit of the amplifier is located in such a way that it is from the rectified Amplifier oscillation is operated in the forward direction and that the feedback loop of the amplifier with the common point of the rectifier element ments (21) and des so that the resistor (22) lying in series is connected (FIG. 1). 11. Circuit according to one or more of the preceding claims, characterized in that the amplifier uses the combination of two with each other RC networks (12, 25) of coupled amplifier elements (1, 2), which when exceeded of the first threshold value acts as a relaxation oscillator (FIG. 2). Documents considered: German Auslegeschrift No. 1,021,025; Luxembourg Patent No. 34,323; Telefunken newspaper, 31 (1958), September, p. 172; Electronics (1955), October, pp. 202, 204, 206, 208.